aLaboratory of Single-Molecule Cell Biology, Kyoto University Graduate School of Biostudies, 606-8501 Kyoto, Japan;dDepartment of Pharmacology, Kyoto University Graduate School of Medicine, 606-8501 Kyoto, Japan

Significance

It remains obscure how actin polymerizing and depolymerizing activities cooperate to control diverse actin dynamics. Formins rotate along the long-pitch helix of F-actin during processive actin elongation (helical rotation), which may twist F-actin in the opposite direction of the cofilin-induced twisting. In this study, we show that a mammalian formin mDia1 generates F-actin resistant to cofilin. Tethered F-actin elongating from immobilized mDia1 contained a less twisted portion in EM analysis and exhibited resistance to the severing activity of cofilin. In cells, overexpression of an active mDia1 mutant, which harbors N-terminal regulatory domains, prolonged F-actin lifetime and accelerated dissociation of cofilin. Helical rotation of formins may thus facilitate the formation of stabilized F-actin resistant to actin severing activities of cofilin.

Abstract

The complex interplay between actin regulatory proteins facilitates the formation of diverse cellular actin structures. Formin homology proteins (formins) play an essential role in the formation of actin stress fibers and yeast actin cables, to which the major actin depolymerizing factor cofilin barely associates. In vitro, F-actin decorated with cofilin exhibits a marked increase in the filament twist. On the other hand, a mammalian formin mDia1 rotates along the long-pitch actin helix during processive actin elongation (helical rotation). Helical rotation may impose torsional force on F-actin in the opposite direction of the cofilin-induced twisting. Here, we show that helical rotation of mDia1 converts F-actin resistant to cofilin both in vivo and in vitro. F-actin assembled by mDia1 without rotational freedom became more resistant to the severing and binding activities of cofilin than freely rotatable F-actin. Electron micrographic analysis revealed untwisting of the long-pitch helix of F-actin elongating from mDia1 on tethering of both mDia1 and the pointed end side of the filament. In cells, single molecules of mDia1ΔC63, an activated mutant containing N-terminal regulatory domains, showed tethering to cell structures more frequently than autoinhibited wild-type mDia1 and mDia1 devoid of N-terminal domains. Overexpression of mDia1ΔC63 induced the formation of F-actin, which has prolonged lifetime and accelerates dissociation of cofilin. Helical rotation of formins may thus serve as an F-actin stabilizing mechanism by which a barbed end-bound molecule can enhance the stability of a filament over a long range.

Physical and social well-being in old age are linked to self-assessments of life worth, and a spectrum of behavioral, economic, health, and social variables may influence whether aging individuals believe they are leading meaningful lives.